Designing future nanomaterials for electromagnetic wave absorption and shielding

Renchao Che; Junwei Gu; Jie Kong; Wei Lu; Yi Huang; Hualiang Lv; Xiaofang Liu; Xiaosi Qi; Guanglei Wu; Hongjing Wu

doi:10.1016/j.xcrp.2025.102502

Designing future nanomaterials for electromagnetic wave absorption and shielding

Renchao Che
, Junwei Gu
, Jie Kong
, Wei Lu
, Yi Huang
, Hualiang Lv
, Xiaofang Liu
, Xiaosi Qi
, Guanglei Wu
, Hongjing Wu

Research output: Contribution to journal › Comment/debate

22 Scopus citations

Abstract

The rapid development of wireless technologies has transformed the applications of electromagnetic (EM) materials from traditional military stealth to broader application in civilian fields. This progress has expanded their frequency range, diversified usage scenarios, and fostered a transition toward nanomaterial-based solutions. Despite these advancements, significant scientific and technical challenges remain, such as the elusive interaction mechanism between nanomaterials and EM waves, overheating caused by EM attenuation, limited attenuation performance of conductive polymers, high EM-wave power consumption, and precise dynamic control of material properties. In this Voices article, we seek answers to the above challenges from a panel of experts.

Original language	English
Article number	102502
Journal	Cell Reports Physical Science
Volume	6
Issue number	3
DOIs	https://doi.org/10.1016/j.xcrp.2025.102502
State	Published - 19 Mar 2025

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10.1016/j.xcrp.2025.102502

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title = "Designing future nanomaterials for electromagnetic wave absorption and shielding",

abstract = "The rapid development of wireless technologies has transformed the applications of electromagnetic (EM) materials from traditional military stealth to broader application in civilian fields. This progress has expanded their frequency range, diversified usage scenarios, and fostered a transition toward nanomaterial-based solutions. Despite these advancements, significant scientific and technical challenges remain, such as the elusive interaction mechanism between nanomaterials and EM waves, overheating caused by EM attenuation, limited attenuation performance of conductive polymers, high EM-wave power consumption, and precise dynamic control of material properties. In this Voices article, we seek answers to the above challenges from a panel of experts.",

author = "Renchao Che and Junwei Gu and Jie Kong and Wei Lu and Yi Huang and Hualiang Lv and Xiaofang Liu and Xiaosi Qi and Guanglei Wu and Hongjing Wu",

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T1 - Designing future nanomaterials for electromagnetic wave absorption and shielding

AU - Che, Renchao

AU - Gu, Junwei

AU - Kong, Jie

AU - Lu, Wei

AU - Huang, Yi

AU - Lv, Hualiang

AU - Liu, Xiaofang

AU - Qi, Xiaosi

AU - Wu, Guanglei

AU - Wu, Hongjing

PY - 2025/3/19

Y1 - 2025/3/19

N2 - The rapid development of wireless technologies has transformed the applications of electromagnetic (EM) materials from traditional military stealth to broader application in civilian fields. This progress has expanded their frequency range, diversified usage scenarios, and fostered a transition toward nanomaterial-based solutions. Despite these advancements, significant scientific and technical challenges remain, such as the elusive interaction mechanism between nanomaterials and EM waves, overheating caused by EM attenuation, limited attenuation performance of conductive polymers, high EM-wave power consumption, and precise dynamic control of material properties. In this Voices article, we seek answers to the above challenges from a panel of experts.

AB - The rapid development of wireless technologies has transformed the applications of electromagnetic (EM) materials from traditional military stealth to broader application in civilian fields. This progress has expanded their frequency range, diversified usage scenarios, and fostered a transition toward nanomaterial-based solutions. Despite these advancements, significant scientific and technical challenges remain, such as the elusive interaction mechanism between nanomaterials and EM waves, overheating caused by EM attenuation, limited attenuation performance of conductive polymers, high EM-wave power consumption, and precise dynamic control of material properties. In this Voices article, we seek answers to the above challenges from a panel of experts.

UR - https://www.scopus.com/pages/publications/86000767516

U2 - 10.1016/j.xcrp.2025.102502

DO - 10.1016/j.xcrp.2025.102502

M3 - 评论/辩论

AN - SCOPUS:86000767516

SN - 2666-3864

VL - 6

JO - Cell Reports Physical Science

JF - Cell Reports Physical Science

IS - 3

M1 - 102502

ER -

Designing future nanomaterials for electromagnetic wave absorption and shielding

Abstract

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